Antenna impedance matching and aperture tuning circuitry

1. Antenna aperture tuning circuitry comprising: a first signal path connected between an antenna radiating element and a ground; a second signal path connected in parallel with the first signal path between the antenna radiating element and the ground; a first LC resonator and a second LC resonator each connected between the first signal path and the ground, wherein the first LC resonator and the second LC resonator are electromagnetically coupled such that a coupling factor between the first LC resonator and the second LC resonator is between about 1.0% and 40.0%; and a third LC resonator and a fourth LC resonator each connected between the second signal path and the ground, wherein the third LC resonator and the fourth LC resonator are electromagnetically coupled such that a coupling factor between the third LC resonator and the fourth LC resonator is between about 1.0% and 40.0%.

2. The antenna aperture tuning circuitry of claim 1 wherein a quality factor of the antenna aperture tuning circuitry is between about 10 and 500.

3. The antenna aperture tuning circuitry of claim 1 wherein the first LC resonator, the second LC resonator, the third LC resonator, and the fourth LC resonator each comprise a resonator inductor coupled in parallel with a resonator capacitor between a common node and the ground.

4. The antenna aperture tuning circuitry of claim 3 further comprising: a first coupling capacitor coupled between the common node of the first LC resonator and the common node of the second LC resonator; and a second coupling capacitor coupled between the common node of the third LC resonator and a common node of the fourth LC resonator.

5. The antenna aperture tuning circuitry of claim 4 wherein a capacitance of the first coupling capacitor and a capacitance of the second coupling capacitor is adjustable.

6. The antenna aperture tuning circuitry of claim 5 wherein a capacitance of the resonator capacitor in each one of the first LC resonator, the second LC resonator, the third LC resonator, and the fourth LC resonator is adjustable.

7. The antenna aperture tuning circuitry of claim 6 further comprising control circuitry configured to adjust the capacitance of one or more of the first coupling capacitor, the second coupling capacitor, the resonator capacitor in the first LC resonator, the resonator capacitor in the second LC resonator, the resonator capacitor in the third LC resonator, and the resonator capacitor in the fourth LC resonator in order to adjust an aperture of the antenna radiating element.

8. The antenna aperture tuning circuitry of claim 7 wherein the antenna aperture tuning circuitry is configured to simultaneously tune the antenna radiating element for at least two different operating bands.

9. Power coupler circuitry comprising: a power coupler configured to couple a portion of electromagnetic power from a transmission line coupled to an antenna, the power coupler comprising: an isolated node; a coupled node; and a coupling line between the isolated node and the coupled node; and a resonator network coupled to the isolated node of the power coupler and comprising: a first LC resonator connected between the isolated node and a ground; and a second LC resonator connected between the isolated node and the ground and electromagnetically coupled with the first LC resonator such that a coupling factor between the first LC resonator and the second LC resonator is between about 1.0% and 40.0%.

10. The power coupler circuitry of claim 9 further comprising a third LC resonator coupled in parallel with one or more of the first LC resonator and the second LC resonator.

11. The power coupler circuitry of claim 10 wherein the first LC resonator, the second LC resonator, and the third LC resonator each comprise a resonator inductor coupled in parallel with a resonator capacitor between a common node and the ground.

12. The power coupler circuitry of claim 11 further comprising: a first coupling capacitor coupled between the common node of the first LC resonator and the common node of the second LC resonator; and a second coupling capacitor coupled between the common node of the first LC resonator and the common node of the third LC resonator.

13. The power coupler circuitry of claim 12 wherein a capacitance of the first coupling capacitor and a capacitance of the second coupling capacitor is adjustable.

14. The power coupler circuitry of claim 13 wherein a capacitance of the resonator capacitor in each one of the first LC resonator, the second LC resonator, and the third LC resonator is adjustable.

15. The power coupler circuitry of claim 14 further comprising control circuitry configured to adjust the capacitance of one or more of the first coupling capacitor, the second coupling capacitor, the resonator capacitor in the first LC resonator, the resonator capacitor in the second LC resonator, and the resonator capacitor in the third LC resonator.

16. The power coupler circuitry of claim 15 wherein the resonator network is configured to simultaneously resonate in at least two different operating bands.

17. Multiplexer and antenna impedance matching circuitry comprising: a first signal path coupled between an antenna node and a first input/output node; a second signal path coupled between the antenna node and a second input/output node; a first LC resonator and a second LC resonator each coupled between the first signal path and a ground, wherein the first LC resonator and the second LC resonator are electromagnetically coupled such that a coupling factor between the first LC resonator and the second LC resonator is between about 1.0% and 40.0%; a third LC resonator and a fourth LC resonator each coupled between the second signal path and the ground, wherein the third LC resonator and the fourth LC resonator are electromagnetically coupled such that a coupling factor between the third LC resonator and the fourth LC resonator is between about 1.0% and 40.0%; and wherein the multiplexer and antenna impedance matching circuitry is configured to: pass signals within a first frequency band between the first input/output node and the antenna node while attenuating signals outside of the first frequency band along the first signal path; pass signals within a second frequency band between the second input/output node and the antenna node while attenuating signals outside of the second frequency band along the second signal path; and match an impedance presented at the antenna node to an impedance presented at one or more of the first input/output node and the second input/output node.

18. The multiplexer and antenna impedance matching circuitry of claim 17 wherein: a coupling factor between the first LC resonator and the third LC resonator is between about 1.0% and 40.0%; a coupling factor between the first LC resonator and the fourth LC resonator is less than about 1.0%; a coupling factor between the second LC resonator and the third LC resonator is less than about 1.0%; and a coupling factor between the second LC resonator and the fourth LC resonator is less than about 1.0%.

19. The multiplexer and antenna impedance matching circuitry of claim 18 wherein: each one of the first LC resonator, the second LC resonator, the third LC resonator, and the fourth LC resonator include a resonator inductor and a resonator capacitor coupled in parallel; and the resonator capacitor of each one of the first LC resonator, the second LC resonator, the third LC resonator, and the fourth LC resonator is adjustable.

20. The multiplexer and antenna impedance matching circuitry of claim 19 further comprising control circuitry configured to adjust a capacitance of the resonator capacitor for each one of the first LC resonator, the second LC resonator, the third LC resonator, and the fourth LC resonator, and a number of coupling capacitors connected between the first LC resonator, the second LC resonator, the third LC resonator, and the fourth LC resonator.